Hydrogeological investigation of the Paine Aquifer considering baseline conditions from 1970 and long - term analysis from 1990 to 2020

Authors

  • Carolina Gamboa Centro de Investigación y Desarrollo de Ecosistemas Hídricos, Facultad de Ingeniería, Ciencia y Tecnología, Universidad ..Bernardo O’Higgins
  • Christian Herrera Centro de Investigación y Desarrollo de Ecosistemas Hídricos, Facultad de Ingeniería, Ciencia y Tecnología, Universidad Bernardo O’Higgins
  • Ximena Salgado Centro de Investigación y Desarrollo de Ecosistemas Hídricos, Facultad de Ingeniería, Ciencia y Tecnología, Universidad Bernardo O’Higgins
  • José Luis Arumi Departamento de recursos hídricos, Universidad de Concepción, Chillán, Chile.
  • Raúl Calderón Centro de Investigación en Recursos Naturales y Sustentabilidad, Universidad Bernardo O’Higgins

DOI:

https://doi.org/10.23854/07199562.2023591.gamboa

Keywords:

Groundwater resources, Mega-drought, temporal analysis, Paine aquifer

Abstract

Groundwater resources are vital for meeting the world's freshwater needs, providing the primary source of drinking water for nearly half the global population, and are particularly important for agriculture and industry in dry regions. The Paine Basin, situated south of Santiago, Chile, has been heavily affected by an extended mega-drought, influencing water availability for various uses. Yet, comprehensive hydrogeological studies to understand the aquifer system and establish a baseline for future actions in the basin to better manage water resources have been lacking. Therefore, this study investigates the aquifer's conditions in 1970, considered  closest to its undisturbed state. It uses water table and chemical data to discern groundwater flow directions and the relationship between the river and the aquifer. Subsequent temporal analyses using Mann-Kendall tests and Theil-Sen slope estimation on DGA well-level data aim to statistically verify the significance of water level declines. The findings confirm an east-to-west groundwater flow, corroborated by chemical signatures linking the Paine waters to the Maipo River, suggesting river recharge from the aquifer during that era. However, recent trends indicate a significant drop in water levels since the mega-drought began in 2010, not aligning with the increase in groundwater extractions starting in 2005. The above highlights that additional water sources, such as river infiltration or irrigation return flow, need to be considered to explain water level variability, which highlights the hydrology of the basin. Finally, trend analysis over the last 30 years indicates that hydrodynamic conditions have changed since the initial conditions were considered in 1970.

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References

BASILIO HAZAS, M., MARCOLINI, G., CASTAGNA, M., GALLI, M., SINGH, T., WOHLMUTH, B. y CHIOGNA, G., 2022. Drought conditions enhance groundwater table fluctuations caused by hydropower plant management. Water Resources Research. Octubre 2022, Vol. 58, no 10, e2022WR032712.

CORFO, 1970. Hidrogeología de la cuenca de Santiago. Parte I y II.

CHENG, D., DUAN, J., QIAN, K., QI, L., YANG, H. y CHEN, X., 2017. Groundwater evapotranspiration under psammophilous vegetation covers in the Mu Us Sandy Land, northern China. Journal of Arid Land. 2017, Vol. 9, p. 98-108.

CHERRY, M. L., GILMORE, T. E., MESSER, T., LI, Y. y WESTROP, J., 2022. A Pivotal New Approach to Groundwater Quality Assessment. ACS ES&T Water. Diciembre 2022, Vol. 2, no 12, p. 2297-2304.

EVANS, S. G., GE, S. y LIANG, S., 2015. Analysis of groundwater flow in mountainous, headwater catchments with permafrost. Water Resources Research. Diciembre 2015, Vol. 51, no 12, p. 9564-9576.

FAYE, S. C., DIONGUE, M. L., POUYE, A., GAYE, C. B., TRAVI, Y., WOHNLICH, S. y TAYLOR, R. G., 2019. Tracing natural groundwater recharge to the Thiaroye aquifer of Dakar, Senegal. Hydrogeology Journal.

GLEESON, T., WADA, Y., BIERKENS, M. F. y VAN BEEK, L. P., 2012. Water balance of global aquifers revealed by groundwater footprint. Nature. Agosto 2012, Vol. 488, no 7410, p. 197-200.

HERRERA, C., URRUTIA, J., GAMBOA, C., SALGADO, X., GODFREY, L., RIVAS, A. y ARRIAGADA, E., 2023. Evaluation of the impact of the intensive exploitation of groundwater and the mega-drought based on the hydrochemical and isotopic composition of the waters of the Chacabuco-Polpaico basin in central Chile. Science of The Total Environment. 2023, 165055.

JÓDAR, J., URRUTIA, J., HERRERA, C., CUSTODIO, E., MARTOS-ROSILLO, S., LAMBÁN, J., 2023. The catastrophic effects of the intensive exploitation of groundwater and mega-drought on aquifers in Central Chile: A projections based from groundwater balance model. Submitted to Science of the Total Environment.

KONIKOW, L. F., 2013. Groundwater depletion in the United States (1900-2008). Reston, Virginia: US Department of the Interior, US Geological Survey. 2013, p. 63.

MOSLEY, L. M., 2015. Drought impacts on the water quality of freshwater systems; review and integration. Earth-Science Reviews. 2015, Vol. 140, p. 203-214.

MUÑOZ, A. A., KLOCK-BARRÍA, K., ALVAREZ-GARRETON, C., AGUILERA-BETTI, I., GONZÁLEZ-REYES, Á., LASTRA, J. A. y LEQUESNE, C., 2020. Water crisis in Petorca Basin, Chile: The combined effects of a mega-drought and water management. Water. 2020, Vol. 12, no 3, 648.

LEQUESNE, C., 2020. Water crisis in Petorca Basin, Chile: The combined effects of a mega-drought and water management. Water. 2020, Vol. 12, no 3, 648.

PEÑA-GUERRERO, M. D., NAUDITT, A., MUÑOZ-ROBLES, C., RIBBE, L. y MEZA, F., 2020. Drought impacts on water quality and potential implications for agricultural production in the Maipo River Basin, Central Chile. Hydrological Sciences Journal. 2020, Vol. 65, no 6, p. 1005-1021.

PHILLIPS, O. M., 2003. Groundwater flow patterns in extensive shallow aquifers with gentle relief: Theory and application to the Galena/Locust Grove region of eastern Maryland. Water resources research. 2003, Vol. 39, no 6.

STROMBERG, J. C., TILLER, R. y RICHTER, B., 1996. Effects of groundwater decline on riparian vegetation of semiarid regions: the San Pedro, Arizona. Ecological Applications. 1996, Vol. 6, no 1, p. 113-131.

TAYLOR, R. G., SCANLON, B., DÖLL, P., RODELL, M., VAN BEEK, R., WADA, Y. y TREIDEL, H., 2013. Ground water and climate change. Nature climate change. 2013, Vol. 3, no 4, p. 322-329.

TAUCARE, M., VIGUIER, B., FIGUEROA, R. y DANIELE, L., 2023. The alarming state of Central Chile's groundwater resources: A paradigmatic case of a lasting overexploitation. Science of The Total Environment. 2023, 167723.

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Published

2023-12-30

How to Cite

Gamboa, C., Herrera, C., Salgado, X., Arumi, J. L., & Calderón, R. (2023). Hydrogeological investigation of the Paine Aquifer considering baseline conditions from 1970 and long - term analysis from 1990 to 2020. Revista Geográfica De Chile Terra Australis, 59. https://doi.org/10.23854/07199562.2023591.gamboa

Issue

Vol. 59 (2023)

Section

Articles

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